It Never Rains But it Pours: Climate Change and Drought

Droughts have been getting a lot of press lately. From affects on agriculture in California to the water rationing in Puerto Rico, and a near miss on rice paddy losses in North Korea; droughts are affecting ecosystems around the globe.

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Climate Change And Drought

Droughts have been getting a lot of press lately. From affects on agriculture in California to the water rationing in Puerto Rico, and a near miss on rice paddy losses in North Korea; droughts are affecting ecosystems around the globe. And then come the floods. Mudslides, eroded banks and a photo on the evening news of a man in a canoe floating down his driveway.

The Frequency And Severity

Sure, we’ve always had droughts; we’ve always had floods.

The difference now is the frequency and severity. Several rounds of climate model predictions have all agreed on a future with a higher frequency of heavy precipitation and drought compared to recent history for many parts of the planet.

What Will This Mean For Plants, Animals And People?

What are the implications for primary productivity, plant growth and adaptation? And how should the known plasticity of plants be accounted for when projecting plant response to future (potentially novel) climates? Researchers from disparate fields are attempting to find out.

Responding To Climate Change

Two recent papers dealing with these questions are included in the PLOS Responding to Climate Change Collection.

The authors attribute the droughts to a combination of changes in climate and human-induced changes on the land. Increasing temperature and declining precipitation are leading to moisture deficits in the region. At the same time, changes in anthropogenic land use practices, such as clearing for agriculture and massive afforestation efforts increased evapotranspiration from the landscape, exacerbating drought.

They found that the impact of water-stress on plant fruit production varied by species, and highlighted several species that appear to be more robust to drought. These species could be targets for future agricultural research on climate-adapted crops. Studies such as these could also highlight species for future research on crop plasticity and adaptation to changes in growing conditions. Such studies will become increasingly important as shifts in climate niches could potentially force species into novel climate regimes.

Mora and colleagues paint a bleak picture for plant production in the absence of significant reduction in emissions, due to a resulting decline in appropriate growing days in many parts of the world.

However, the authors also assume no plasticity in plant responses to climate shifts outside the currently experienced averages, despite ample evidence of the ability of plants to exist outside their historical ranges.

The Variation In Adaptability

Additional evidence is needed on the responses of individual plants species as well as communities, to novel climate regimes, as well as the mechanisms behind those responses, and the consequences for variation in adaptability across species and functional groups.